The growth of density perturbations in the last ∼10 billion years from tomographic large-scale structure data
Journal of Cosmology and Astroparticle Physics IOP Publishing 10:2021 (2021) 030
Authors:
Carlos Garcia-Garcia, Jaime Ruiz Zapatero, David Alonso, Emilio Bellini, Pedro Ferreira, Eva Mueller, Andrina Nicola, Pilar Ruiz-Lapuente
Abstract:
In order to investigate the origin of the ongoing tension between the amplitude
of matter fluctuations measured by weak lensing experiments at low redshifts and the value
inferred from the cosmic microwave background anisotropies, we reconstruct the evolution of
this amplitude from z ∼ 2 using existing large-scale structure data. To do so, we decouple
the linear growth of density inhomogeneities from the background expansion, and constrain
its redshift dependence making use of a combination of 6 different data sets, including cosmic shear, galaxy clustering and CMB lensing. We analyze these data under a consistent
harmonic-space angular power spectrum-based pipeline. We show that current data constrain the amplitude of fluctuations mostly in the range 0.2 < z < 0.7, where it is lower than
predicted by Planck. This difference is mostly driven by current cosmic shear data, although
the growth histories reconstructed from different data combinations are consistent with each
other, and we find no evidence of systematic deviations in any particular experiment. In
spite of the tension with Planck, the data are well-described by the ΛCDM model, albeit
with a lower value of S8 ≡ σ8(Ωm/0.3)0.5
. As part of our analysis, we find constraints on
this parameter of S8 = 0.7781 ± 0.0094 (68% confidence level), reaching almost percent-level
errors comparable with CMB measurements, and 3.4σ away from the value found by Planck.
